Bilaterally expanding intervertebral body fusion device

ABSTRACT

An embodiment includes an expandable intervertebral body fusion device with two expansion wedges within a generally hollow main body. After implantation into the intervertebral disc space, the expansion wedges are simultaneously moved from the center of the device toward the ends, which flexes the arms of the cage and increases the size of the implant. This expansion stabilizes the device in the disc space and increases the disc height, thereby reducing foraminal compression of spinal nerves and creating a stable motion segment for eventual fusion. Other embodiments are described herein.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a continuation of U.S. patent application Ser. No.14/730,876, filed Jun. 4, 2015, which claims priority to U.S.Provisional Patent Application No. 62/007,500 filed on Jun. 4, 2014 andentitled “Bilaterally expanding intervertebral body fusion device”, thecontent of which is hereby incorporated by reference.

TECHNICAL FIELD

Embodiments of the invention are in the field of implantable boneimplants or prostheses and the surgical techniques for using them.

BACKGROUND

U.S. Pat. No. 8,435,299 describes an expandable osteosynthesis cage. Anembodiment described therein concerns an implant designed to be slid orinserted from a posterior direction between the facing faces of twoconsecutive vertebrae in order to maintain a given distance between themand to restore the stability of the spinal column (e.g., after a failureof the corresponding joint) by fixing the two vertebrae together.

The patent addresses several techniques for restoring a “normal” lumbarlordosis such as, for example, implanting either a graft (which in timefuses the vertebrae together) or a prosthesis (which fixes them togetherimmediately) while still also making it possible in time to achievefusion between the vertebra. One such prosthesis is a “cage”, which ishollow and rigid with inside/outside intercommunication slots forreceiving a bone graft which, via the slots, subsequently fuses with theadjacent vertebrae on either side.

The patent addresses various types of cages including those having twosubstantially parallel branches connected to a rigid body through whichit is possible to turn a worm screw system. The worm screw system thenmoves a wedge in screw engagement on the screw from an initial positionclose to the distal ends of the branches towards the body linking thebranches together, thereby splaying the two branches apart angularly. Itis then possible to insert such a cage of initially flat shape betweenthe vertebrae, and then by turning the drive axis of the wedge, thedesired angle between the branches is adjusted or set from a posterioraccess. Such devices are more complex mechanically and leave a smallerinside volume for the fusion graft. Also, because of their flat shapeeven though they are better at ensuring a given bearing angle betweenthe vertebrae, they require a passage of the same rectangular section tobe prepared to receive them, and that complicates implementation.

BRIEF DESCRIPTION OF THE DRAWINGS

Features and advantages of embodiments of the present invention willbecome apparent from the appended claims, the following detaileddescription of one or more example embodiments, and the correspondingfigures. Where considered appropriate, reference labels have beenrepeated among the figures to indicate corresponding or analogouselements.

FIG. 1a includes a perspective view of an embodiment shown in its“unexpanded” state. FIG. 1b includes a perspective view of theembodiment of FIG. 1a shown in its “expanded” state. FIG. 1c includes across section of the embodiment of FIG. 1a shown with wedges in“unexpanded” position. FIG. 1d includes a cross section of theembodiment of FIG. 1a shown with wedges in “expanded” position.

FIG. 2a includes a disassembled embodiment of an implant system. FIG. 2bincludes an assembled embodiment of an implant system in its unexpandedform. FIG. 2c includes an assembled embodiment of an implant system inits expanded form.

FIG. 3a includes a perspective view of an embodiment shown in its“unexpanded” state. FIG. 3b includes a front view of the embodiment ofFIG. 3a in its unexpanded state.

FIG. 4a includes a front view of an embodiment in its unexpanded state.FIG. 4b includes a front view of the embodiment of FIG. 4a havingundergone symmetric bi-lateral expansion. FIG. 4c includes a front viewof the embodiment of FIG. 4a having undergone lateral expansion greaterthan vertical expansion. FIG. 4d includes a front view of the embodimentof FIG. 4a having undergone vertical expansion greater than horizontalexpansion. FIG. 4e includes a front view of the embodiment of FIG. 4ahaving undergone unequal expansion amongst the branches.

DETAILED DESCRIPTION

Reference will now be made to the drawings wherein like structures maybe provided with like suffix reference designations. Additionalstructures known in the art may not have been included to maintain theclarity of the drawings. In the following description, numerous specificdetails are set forth but embodiments of the invention may be practicedwithout these specific details. Well-known structures and techniqueshave not been shown in detail to avoid obscuring an understanding ofthis description. “An embodiment”, “various embodiments” and the likeindicate embodiment(s) so described may include particular features,structures, or characteristics, but not every embodiment necessarilyincludes the particular features, structures, or characteristics. Someembodiments may have some, all, or none of the features described forother embodiments. “First”, “second”, “third” and the like describe acommon object and indicate different instances of like objects are beingreferred to. Such adjectives do not imply objects so described must bein a given sequence, either temporally, spatially, in ranking, or in anyother manner. “Connected” may indicate elements are in direct physicalor electrical contact with each other and “coupled” may indicateelements co-operate or interact with each other, but they may or may notbe in direct physical or electrical contact.

FIG. 1a includes a perspective view of an embodiment shown in its“unexpanded” state. FIG. 1b includes a perspective view of theembodiment of FIG. 1a shown in its “expanded” state. FIG. 1c includes across section of the embodiment of FIG. 1a shown with wedges in“unexpanded” position. FIG. 1d includes a cross section of theembodiment of FIG. 1a shown with wedges in “expanded” position.

An embodiment consists of an expandable intervertebral body fusiondevice 100 with two expansion wedges 111, 112 within a generally hollowmain body. After implantation into the intervertebral disc space, theexpansion wedges are simultaneously moved from the center of the devicetoward the lateral ends, which flexes the arms 101, 102, 103, 104, 105,106, 107, 108 of the cage 100 and increases the size of the implant.This expansion stabilizes the device in the disc space and increases thedisc height, thereby reducing foraminal compression of spinal nerves andcreating a stable motion segment for eventual fusion.

Many examples of conventional technology limit expansion features toonly one end of the intervertebral fusion device. This limits theorientation of the device to be in a primarily anterior-posteriordirection to replicate the physiological curvature of the spine. Incontrast, an embodiment permits simultaneous bilateral expansion of theintervertebral fusion device. The cage 100 can be oriented in a lateralor oblique orientation in the disc space, and will not induce any ormuch scoliotic angle after expansion. Such a cage may be referred to asa direct lateral interbody fusion (DLIF) cage, indicating the cage isspecifically configured for a lateral approach.

Expandable intervertebral body fusion device 100 consists of a main bodywith multiple flexible arms (also called branches) 101, 102, 103, 104,105, 106, 107, 108 originating from the center of the device, andextending generally parallel to the long axis 131 of the body. Withinthe body, and between the arms, are two slidable expansion wedges (alsocalled spacers) 111, 112 which, when translated from the center of thebody toward the ends, force the arms to flex radially outward. Thisincreases the effective size of the device.

FIG. 2a includes a disassembled embodiment of an implant system. FIG. 2bincludes an assembled embodiment of an implant system in its unexpandedform. FIG. 2c includes an assembled embodiment of an implant system inits expanded form.

In FIG. 2b , translation of the wedges 211, 212 is accomplished byinstrument system 280, a portion of which (rods 242, 243) are insertedthrough one end of the body, and attach to each wedge. One instrument242 pushes on the distal wedge 211, while another instrument 243simultaneously pulls on the proximal wedge 212. Instrument 243 may bereferred to as a “proximal expander” that is attached to the proximalwedge 212. Instrument 242 may be referred to as a “distal expander” thatis attached to the distal wedge 211 after being inserted throughproximal expander 243. Portion 241 may be referred to as “expander knob”and may be threaded onto proximal expander 243. As knob 241 is rotatedand threads onto proximal expander 243, it simultaneously pushes ondistal wedge 211 and pulls on proximal wedge 212 until both wedges fullyadvance towards ends of interbody device 100. Threads 234 helps “screw”the implant into position by traversing the vertebrae.

An embodiment facilitates fusion of an intervertebral disc space.Specifically, the length permitted by the design of cage 100, along thesymmetric expansion capability (described below in conjunction withFIGS. 4a-e , allows for a direct lateral surgical approach to theintervertebral disc. However, an embodiment is not so limited and may beused for fracture stabilization, fusion of the sacro-iliac joint, facetjoint fixation, and the like.

The embodiment of FIG. 1 describes a generally cylindrical, threadeddevice. Cage 100 may be implanted into the intervertebral disc space byrotation, whereby the threads 150 advance the cage 100 until finalplacement is achieved.

FIG. 3a includes a perspective view of an embodiment shown in its“unexpanded” state. FIG. 3b includes a front view of the embodiment ofFIG. 3a in its unexpanded state.

An embodiment includes a device 300 which has the same overalldimensions as cage 100, but is generally rectangular in cross-section.Rather than threads 150, the device has “teeth” 351 on the inferior andsuperior surfaces, intended to grip adjacent vertebral end plates. Theembodiment is advanced into the intervertebral disc space by impactionon the proximal face of the implant rather than by rotation. Cage 300includes first branches 301, 302, 303, 304 and second branches 305, 307,308 and another branch not easily seen in FIG. 3 a.

Returning to FIG. 1a , cage 100 has expansion wedges 111, 112 that arecircular in cross section, and a body which has an internal bore withcircular or conical cross section. This provides for equal expansion ofarms 101, 102, 103, 104, 105, 106, 107, 108 in both anterior andposterior directions as well as superior and inferior directions. Analternative embodiment has elliptical or rectangular cross sections (orgenerally asymmetric) for either the wedges and/or interior ramps (e.g.,some ramps are thicker than other ramps with thicker ramps to causegreater expansion of their corresponding branches) and cross-sectionsupon which the wedges traverse. As described immediately below, thisallows for differential expansion of the arms (e.g., arms expand more inthe anterior/posterior directions than in the superior/inferiordirections, or vice-versa).

FIG. 4a includes a front view of an embodiment in its unexpanded state.FIG. 4b includes a front view of the embodiment of FIG. 4a with arms401, 402, 403, 404 having undergone symmetric expansion. FIG. 4cincludes a front view of the embodiment of FIG. 4a having undergonelateral expansion that is greater than vertical expansion. In otherwords, expansion along lines 441, 442 are greater horizontally(anterior/posterior) than vertically (superior/inferior). FIG. 4dincludes a front view of the embodiment of FIG. 4a having undergonevertical expansion that is greater than horizontal expansion. In otherwords, expansion along lines 441, 442 are lesser horizontally(anterior/posterior) than vertically (superior/inferior).

FIG. 4e includes a front view of the embodiment of FIG. 4a havingundergone unequal expansion. In other words, expansion along lines 441,442 are greater horizontally (anterior/posterior) and vertically(superior/inferior) for arms 403, 404 than for arms 401, 402. Forexample, greater expansion with a device such as the one shown in FIG.4e may provide for greater expansion to the anterior side in the lumbarregion. In FIG. 4(e) direction 443 may provide that location 444 isanterior in some embodiments or inferior in other embodiments whereaslocation 445 may be posterior in some embodiment or superior in otherembodiments.

Still referring to FIG. 4e for example, one of the first branches (e.g.,branch 404) deflects radially a first distance from the long axis (i.e.,where first distance is taken orthogonal to axis 431) when the firstspacer is secured by the one or more first shoulders (i.e., upon fulldeployment of spacer to its lateral-most position); wherein another ofthe first branches (e.g., branch 401) deflects radially a seconddistance from the long axis (i.e., where second distance is takenorthogonal to axis 431) when the first spacer is secured by the one ormore first shoulders; wherein the first distance is unequal to thesecond distance. For example, branch 404 may deflect away from axis 431to a greater extent than branch 401 because the spacer causing thebranches to deflect may be non-circular in cross-section and may be moreintrusive on branch 404 than branch 401. Thus, distance 446 may begreater than distance 447. In an embodiment, an additional one of thefirst branches is located between the one of the first branches and theanother of the first branches. For example, in an embodiment branch 404deflects from axis 431 to a greater degree than branch 402 (i.e.,distance 448 is less than distance 446). In this case, branches 402, 404are separated from each other by either or both of branches 401, 403.

Along those lines, embodiments are suitable for lumbar, thoracic, andcervical applications and surgeons may select the type of expansiondesired (and the corresponding cage to use) based on the implant site(e.g., lumbar vs. thoracic).

Thus, embodiments described herein provide for a longer device thanfound with traditional devices that only include a single spacer orwedge advancing along an anterior/posterior route. Such an embodimentallows for expansion on both ends of device, shares physiologic loadsacross more points, reducing stress at each arm, and expands clinicalutility of the device by allowing additional surgical approaches (e.g.,lateral with a DLIF cage).

As used herein “simultaneous” just requires overlap at at least onemoment time (e.g., a millisecond) of the deployment and does notnecessarily require both wedges to start and/or stop deployment at anidentical moment or moments in time.

An embodiment does not require simultaneous expansion but may allow fora first wedge to move into an expanded state followed by a second wedgemoving into an expanded state.

An embodiment may provide simultaneous expansion that is asynchronous.For example, with FIG. 2c wedges 211 and 212 may be moving at the sametime (towards locations 240, 236) but wedge 212 may be at location 237while wedge 211 is at location 239 (wherein the distance betweenlocations midline 238 and 237 is smaller than the distance betweenmidline 238 and 239).

The embodiment of FIG. 1 illustrates 8 arms, 4 of which are deployed bythe proximal wedge and 4 of which are deployed by the distal wedge.However, another embodiment may provide for a total of 4 arms, 2 ofwhich are deployed by the proximal wedge and 2 of which are deployed bythe distal wedge. For example, the “2 of which are deployed by theproximal wedge” may include a superior arm and an inferior arm. Thesuperior arm and/or inferior arm may each have an aperture within saidarm. That aperture may pass completely through the arm while having aperimeter completely enclosed by the arm. For example, the arm may havea torus or donut portion. The arm may include a rectangular toroid shapeor toroid with rectangular cross-section (e.g., rectangle with holepassing through it). The same may be true for the arms deployed bydistal wedge. In such an embodiment the tips of the arm may not splayaway from each other because those tips may be connected to one another.Another embodiment does not necessarily include symmetry in the numberof arms. For example, the distal portion of the embodiment may have anumber of arms (e.g., 3) and the proximal portion may include more(e.g., 4 or 5) or less (2) arms.

Any of the arms discussed above may have bilateral expansion (horizontaland vertical, as seen in FIGS. 4a and 4e ) or may move only verticallyor horizontally (or may be have just one arm or a few arms of severalarms move/spread out during device deployment).

The following examples pertain to further embodiments.

Example 1 includes an intervertebral spacing implant system comprising afirst seat having a first lateral end. Such a seat may include, forexample, portion 121′ of FIG. 1a with a second seat portion indicated byportion 121″. Cage 100 includes first branches (101, 102, 103, 104)coupled to the first lateral end of the first seat and extending in afirst lateral direction away from the first seat. The first seat and thefirst branches form a first cage defining a first internal volume. Sucha volume is indicated by volume 122 with a corresponding volume at 123.Each first branch has a first inward side and a first outward side. FIG.1c indicates branch or arm 102 having a ramp 124 as well as smooth,non-threaded shoulder 125. A first spacer (e.g., spacer 111) isconfigured to fit within the first cage and move in the first lateraldirection (e.g., direction 126) upon the urging of a spacer-advancinginstrument (e.g., system 280 of FIG. 2), the first spacer and first cageconfigured such that one or more first branches will move from anunextended position to an extended position when the first spacer isurged in the first lateral direction; one or more first shoulders (e.g.,shoulder 125) formed on the first inward side of one or more firstbranches, the one or more first shoulders configured to reversiblysecure the first spacer near a first lateral end of the first branches.By being reversible, this allows for a spacer to be withdrawn or movedto center of cage 100 (i.e., towards seat 121). The spacer can bereversible based on contour edges of both the spacer (not shown) and/orshoulder (e.g., shoulder 125). The first internal volume between thefirst lateral end of the first seat and the first spacer is unoccupiedby any link member when the first spacer is secured by the one or morefirst shoulders. The second cage comprising arms 105, 105, 107, 108functions similarly to the first cage including arms 101, 102, 103, 104.The embodiment may include a second seat (e.g., portion 121″) having asecond lateral end; second branches coupled to the second lateral end ofthe second seat and extending in a second lateral direction (e.g.,direction 127) away from the second seat, the second seat and the secondbranches forming a second cage defining a second internal volume, eachsecond branch having a second inward side and a second outward side; asecond spacer configured to fit within the second cage and move in thesecond lateral direction upon the urging of the spacer-advancinginstrument, the second spacer and the second cage configured such thatone or more second branches will move from an unextended position to anextended position when the second spacer is urged in the second lateraldirection; one or more second shoulders formed on the inward side of oneor more second branches, the one or more second shoulders configured toreversibly secure the second spacer near a second lateral end of thesecond plurality of branches; wherein the second internal volume betweenthe second proximal end of the second seat and the second spacer isunoccupied by any link member when the second spacer is secured by theone or more second shoulders; wherein the first seat, second seat, firstbranches, and second branches are all monolithic with each other. Thus,portions 121′, 121″, and arms 101, 102, 103, 104, 105, 106, 107, 108 areall formed from a single element without welds, adhesives, and the like(i.e. monolithic). For example, the portions are machined from a singleblock of material, such as titanium or steel.

In example 2 the subject matter of the Example 1 can optionally includewherein an outside general shape of each of the first and second cagesis at least one of cylindrical and quasi-cylindrical when the first andsecond branches are in an unextended position; wherein an outsidegeneral shape of the first and second cages is frustoconical, flaringaway respectively from the first and second seats, when one or morefirst and second branches are in an extended position. An embodimentincludes an outside general shape of each of the first and second cagesas being ovoid or quasi-ovoid.

In some embodiments, the lateral ends may have heights 133, 135 that areless than height 132 of seat 121 before expansion (FIG. 1c ). However,the lateral ends may have heights 133, 135 that are greater than height132 of seat 121 after expansion (FIG. 1d ). Further, outside walls suchas the area populated by threads 134 may be bowed or curved beforeexpansion with the curvature removed after expansion while in otherembodiments the outside walls such as the area populated by threads 134may be bowed or curved after expansion with the curvature removed beforeexpansion. Such embodiments may have varying load ratings and may bemore appropriate for different locations (e.g., cervical vs. lumbar).

In example 3 the subject matter of the Examples 1-2 can optionallyinclude wherein the spacer-advancing instrument is configured tosimultaneously advance the first and second spacers in the first andsecond lateral directions in response to rotating a portion of thespacer-advancing instrument.

Other embodiments may deploy the first and second spacers in differingways. For example, a ratchet system with a “trigger” system may be usedto manipulate cage deployment modules, such as units 242, 243 of FIG. 2a(i.e., without necessarily requiring rotation of any instrumentportion).

In example 4 the subject matter of the Examples 1-3 can optionallyinclude wherein the spacer-advancing instrument is configured toasynchronously and simultaneously laterally advance the first and secondspacers in response to rotating a portion of the spacer-advancinginstrument.

In example 5 the subject matter of the Examples 1-4 can optionallyinclude wherein the first and second cages comprise a direct lateralinterbody fusion (DLIF) cage.

In example 6 the subject matter of the Examples 1-5 can optionallyinclude wherein the first inward side of each first branch and thesecond inward side of each second branch is smooth and is not threaded.

In example 7 the subject matter of the Examples 1-6 can optionallyinclude wherein a long axis (e.g., axis 131) extends centrally withinthe first and second cages along the first and second lateral directions(e.g., directions 126, 127); wherein one of the first branches deflectsradially a first distance from the long axis when the first spacer issecured by the one or more first shoulders; wherein another of the firstbranches deflects radially a second distance from the long axis when thefirst spacer is secured by the one or more first shoulders; wherein thefirst distance is unequal to the second distance.

In example 8 the subject matter of the Examples 1-7 can optionallyinclude wherein an additional one of the first branches is locatedbetween the one of the first branches and the another of the firstbranches.

In example 9 the subject matter of the Examples 1-8 can optionallyinclude wherein the first and second seats each include across-sectional profile, in a plane orthogonal to the long axis, whichis substantially cylindrical. For example, FIG. 1a has a “generally” or“substantially” cylindrical cross-section at seat 121, or seat portions121′, 121″ (regardless of small flat portions shown in FIG. 1a ). Infact, those cross-sections are generally or substantially circular,whereas the seat 321 of cage 300 in FIG. 3a has a generally cylindricalcross-section seat 321 but does not have a generally or substantiallycircular cross-section.

In example 10 the subject matter of the Examples 1-9 can optionallyinclude wherein the first branches that move from an unextended positionto an extended position when the first spacer is urged in the firstlateral direction further comprise the first one or more shoulders;wherein the first spacer comprises a first connector (e.g., internalthreads for spacer 111) to removably couple the first spacer to thespacer-advancing instrument; wherein the second branches that move froman unextended position to an extended position when the second spacer isurged in the second lateral direction further comprise the second one ormore shoulders; wherein the second spacer comprises a second connectorto removably couple the second spacer to the spacer-advancinginstrument.

In example 11 the subject matter of the Examples 1-10 can optionallyinclude wherein the first branches are configured to enable bilateralexpansion of the implant and the second branches are configured toenable bilateral expansion of the implant.

In example 12 the subject matter of the Examples 1-11 can optionallyinclude a first orifice extending from the first internal volume (e.g.,space 122) of the first cage and through the first seat (e.g., portion121′) to the second seat (e.g., portion 121″), the orifice configured toallow the spacer-advancing instrument to pass through; a second orificeextending from the second internal volume (e.g., space 123) of thesecond cage and through the second seat to the first seat, the secondorifice configured to allow the spacer-advancing instrument to passthrough.

As used herein, a first seat and a second seat may be portions of alarger surface. For example, portions 121′ and 121″ are both portions ofsurface 121. Thus, the first and second cages of Example 1 may bereferred to as first and second cage portions.

In example 13 the subject matter of the Examples 1-12 can optionallyinclude a plug, wherein at least one of the first and second spacersincludes an orifice configured to sealingly mate with the plug. Forexample, spacer 112 of FIG. 1d has internal threads to mate withinsertion device 200 of FIG. 2a . After spacer 112 is fully laterallydeployed bone particulate or other graft/bone generating material may beplaced in spaces 122, 123. Afterwards, a plug may be added to aperturewithin spacer 112 to seal the space 123 and pack the bone generatingmaterial within cage 100. An embodiment may include another plug to fitwithin the orifice of spacer 111 (or a plug for spacer 111 but notspacer 112).

In example 14 the subject matter of the Examples 1-13 can optionallyinclude wherein at least a portion of the first internal volume is inthe form of a truncated cone when the first branches are in anunextended position; wherein at least a portion of the second internalvolume is in the form of a truncated cone when the second branches arein an unextended position.

In example 15 the subject matter of the Examples 1-14 can optionallyinclude wherein the implant comprises a first plurality of spacers forthe first cage and a second plurality of cages for the second cage. Theadditional spacers may have a terminal or fully deployed stage midwayalong the proximal and distal cages to provide greater support.

In example 16 the subject matter of the Examples 1-14 can optionallyinclude wherein the first seat comprises one or more first flat surfaces(e.g., portion 121′) between the second seat and the first lateral end;wherein the second seat comprises one or more second flat surfaces(e.g., portion 121″) between the first seat and the second lateral end.

In example 17 the subject matter of the Examples 1-16 can optionallyinclude wherein a first medial edge of a perimeter of the first spaceris tapered; wherein a second medial edge of a perimeter of the secondspacer is tapered. Thus, for inner edges of spacers (edges closest toseat) may be tapered to help promote reversibility so a fully deployedspacer can be withdrawn and the cage can be collapsed (fully orpartially).

In example 18 the subject matter of the Examples 1-17 can optionallyinclude wherein the first seat and first branches form a unitarystructure and the second seat and second branches form a second unitarystructure.

In example 19 the subject matter of the Examples 1-18 can optionallyinclude wherein two of the first branches partially define a first slot(e.g., slot 128) configured to allow fusion between graft material and avertebra; wherein two of the second branches partially define a secondslot (e.g., slot 129) configured to allow fusion between the graftmaterial and the vertebra.

In example 20 the subject matter of the Examples 1-19 can optionallyinclude wherein the first seat, the first spacer, and the two firstbranches define the first slot when one or more first branches are in anextended position; wherein the second seat, the second spacer, and thetwo second branches define the second slot when one or more secondbranches are in an extended position.

In example 21 the subject matter of the Examples 1-20 can optionallyinclude wherein an additional two of the first branches partially definean additional slot configured to allow fusion between the graft materialand an additional vertebra.

In example 22 the subject matter of the Examples 1-21 can optionallyinclude wherein the first seat, the first spacer, and the firstadditional two branches define the additional slot when one or morefirst branches are in an extended position.

In example 23 the subject matter of the Examples 1-22 can optionallyinclude wherein the first branches comprise three or more branches andthe second branches comprise three or more branches; wherein the firstlateral ends of two or more first branches may connect to one anotherand second lateral ends of two or more of the second branches connect toone another; wherein at least a portion of the outward side of one ormore first branches comprises ridges; wherein the extended position isan active position and the unextended position is a rest position.

In example 24 the subject matter of the Examples 1-23 can optionallyinclude the spacer-advancing instrument, wherein the spacer-advancinginstrument includes a plurality of threaded rods.

In example 25 the subject matter of the Examples 1-24 can optionallyinclude wherein the spacer-advancing instrument is configured tosimultaneously advance the first and second spacers in the first andsecond lateral directions in response to advancing a pushing module inat least one of the first and second lateral directions. For example, atrigger based ratchet system may include a module, such as a rodconfigured to mate with a spacer and advance or withdraw the spacer.

In example 25 the subject matter of the Examples 1-24 can optionallyinclude wherein a first lateral-most edge portion of the first brancheshas a first unexpanded height when the first spacer is not secured bythe one or more first shoulders and a first expanded height when thefirst spacer is secured by the one or more first shoulders; wherein asecond lateral-most edge portion of the second branches has a secondunexpanded height when the second spacer is not secured by the one ormore second shoulders and a second expanded height when the secondspacer is secured by the one or more second shoulders; wherein the firstseat has a first seat height; wherein the first seat height is (a)greater than the first and second unexpanded heights, and (b) less thanthe first and second expanded heights.

For example, height 132 is greater than height 133, 135 of FIG. 1c butless than height 133, 135 of FIG. 1d . In other embodiments (not shown),height 132 is greater than height 133, 135 of FIG. 1c but substantially(+/−5%) equal to height 133, 135 of FIG. 1d . In other embodiments (notshown), height 132 is substantially (+/−5%) equal to height 133, 135 ofFIG. 1c but less than height 133, 135 of FIG. 1 d.

While the present invention has been described with respect to a limitednumber of embodiments, those skilled in the art will appreciate numerousmodifications and variations therefrom. It is intended that the appendedclaims cover all such modifications and variations as fall within thetrue spirit and scope of this present invention.

What is claimed is:
 1. An intervertebral spacing implant systemcomprising: a first seat having a first lateral end; first branchescoupled to the first lateral end of the first seat and extending in afirst lateral direction away from the first seat, the first seat and thefirst branches forming a first cage defining a first internal volume,each first branch having a first inward side and a first outward side; afirst spacer configured to fit within the first cage and move in thefirst lateral direction upon the urging of a spacer-advancinginstrument, the first spacer and first cage configured such that one ormore first branches will move from an unextended position to a fullyextended position when the first spacer is urged in the first lateraldirection; wherein the first internal volume between the first lateralend of the first seat and the first spacer is unoccupied by any linkmember when the one or more first branches are in the fully extendedposition; a second seat having a second lateral end; second branchescoupled to the second lateral end of the second seat and extending in asecond lateral direction away from the second seat, the second seat andthe second branches forming a second cage defining a second internalvolume, each second branch having a second inward side and a secondoutward side; a second spacer configured to fit within the second cageand move in the second lateral direction upon the urging of thespacer-advancing instrument, the second spacer and the second cageconfigured such that one or more second branches will move from anunextended position to a fully extended position when the second spaceris urged in the second lateral direction; wherein the second internalvolume between the second proximal end of the second seat and the secondspacer is unoccupied by any link member when the one or more secondbranches are in the fully extended position; wherein a long axis extendscentrally within the first and second cages along the first and secondlateral directions; wherein one of the first branches deflects radiallya first distance, orthogonal to the long axis, when the one or morefirst branches are in the fully extended position; wherein another ofthe first branches deflects radially a second distance, orthogonal tothe long axis, when the one or more first branches are in the fullyextended position; wherein the first distance is unequal to the seconddistance.
 2. The intervertebral spacing implant system of claim 1,wherein the spacer-advancing instrument is configured to simultaneouslyadvance the first and second spacers in the first and second lateraldirections in response to rotating a portion of the spacer-advancinginstrument.
 3. The intervertebral spacing implant system of claim 2,wherein the spacer-advancing instrument is configured to asynchronouslyand simultaneously laterally advance the first and second spacers inresponse to rotating the portion of the spacer-advancing instrument. 4.The intervertebral spacing implant system of claim 1, wherein the firstand second cages comprise a direct lateral interbody fusion (DLIF) cage.5. The intervertebral spacing implant system of claim 1, wherein anadditional one of the first branches is located between the one of thefirst branches and the another of the first branches.
 6. Theintervertebral spacing implant system of claim 1 comprising: a firstorifice extending from the first internal volume of the first cage andthrough the first seat to the second seat, the orifice configured toallow the spacer-advancing instrument to pass through; a second orificeextending from the second internal volume of the second cage and throughthe second seat to the first seat, the second orifice configured toallow the spacer-advancing instrument to pass through wherein the firstand second seats are non-resilient.
 7. The intervertebral spacingimplant system of claim 1, wherein a first lateral-most edge portion ofthe first branches has a first unexpanded height when the one or morefirst branches are in the unextended position and a first expandedheight when the one or more first branches are in the fully extendedposition; wherein a second lateral-most edge portion of the secondbranches has a second unexpanded height when the one or more secondbranches are in the unextended position and a second expanded heightwhen the one or more second branches are in the fully extended position;wherein the first seat has a first seat height; wherein the first seatheight is (a) greater than the first and second unexpanded heights, and(b) less than the first and second expanded heights.
 8. Theintervertebral spacing implant system of claim 1, wherein the first seatcomprises one or more first flat surfaces between the second seat andthe first lateral end; wherein the second seat comprises one or moresecond flat surfaces between the first seat and the second lateral end;wherein the first lateral direction is opposite the second lateraldirection.
 9. The intervertebral spacing implant of claim 1, wherein thefirst seat and first branches form a unitary structure and the secondseat and second branches form a second unitary structure.
 10. Anintervertebral spacing implant system comprising: a first seat having afirst lateral end; first branches coupled to the first lateral end ofthe first seat and extending in a first lateral direction away from thefirst seat, the first seat and the first branches forming a first cagedefining a first internal volume, each first branch having a firstinward side and a first outward side; a first spacer configured to fitwithin the first cage and move in the first lateral direction upon theurging of a spacer-advancing instrument, the first spacer and first cageconfigured such that one or more first branches will move from anunextended position to a fully extended position when the first spaceris urged in the first lateral direction; wherein the first internalvolume between the first lateral end of the first seat and the firstspacer is unoccupied by any link member when the one or more firstbranches are in the fully extended position; a second seat having asecond lateral end; second branches coupled to the second lateral end ofthe second seat and extending in a second lateral direction away fromthe second seat, the second seat and the second branches forming asecond cage defining a second internal volume, each second branch havinga second inward side and a second outward side; a second spacerconfigured to fit within the second cage and move in the second lateraldirection upon the urging of the spacer-advancing instrument, the secondspacer and the second cage configured such that one or more secondbranches will move from an unextended position to a fully extendedposition when the second spacer is urged in the second lateraldirection; wherein the second internal volume between the secondproximal end of the second seat and the second spacer is unoccupied byany link member when the one or more second branches are in the fullyextended position; wherein the first and second cages comprise a directlateral interbody fusion (DLIF) cage.
 11. The intervertebral spacingimplant system of claim 10, wherein the spacer-advancing instrument isconfigured to simultaneously advance the first and second spacers in thefirst and second lateral directions in response to rotating a portion ofthe spacer-advancing instrument.
 12. The intervertebral spacing implantsystem of claim 11, wherein the spacer-advancing instrument isconfigured to asynchronously and simultaneously laterally advance thefirst and second spacers in response to rotating a portion of thespacer-advancing instrument.
 13. The intervertebral spacing implantsystem of claim 10, wherein an additional one of the first branches islocated between the one of the first branches and the another of thefirst branches.
 14. The intervertebral spacing implant system of claim10 comprising: a first orifice extending from the first internal volumeof the first cage and through the first seat to the second seat, theorifice configured to allow the spacer-advancing instrument to passthrough; a second orifice extending from the second internal volume ofthe second cage and through the second seat to the first seat, thesecond orifice configured to allow the spacer-advancing instrument topass through wherein the first and second seats are non-resilient. 15.An intervertebral spacing implant system comprising: a first seat havinga first lateral end; first branches coupled to the first lateral end ofthe first seat and extending in a first lateral direction away from thefirst seat, the first seat and the first branches forming a first cagedefining a first internal volume, each first branch having a firstinward side and a first outward side; a first spacer configured to fitwithin the first cage and move in the first lateral direction upon theurging of a spacer-advancing instrument, the first spacer and first cageconfigured such that one or more first branches will move from anunextended position to a fully extended position when the first spaceris urged in the first lateral direction; wherein the first internalvolume between the first lateral end of the first seat and the firstspacer is unoccupied by any link member when the one or more firstbranches are in the fully extended position; a second seat having asecond lateral end; second branches coupled to the second lateral end ofthe second seat and extending in a second lateral direction away fromthe second seat, the second seat and the second branches forming asecond cage defining a second internal volume, each second branch havinga second inward side and a second outward side; a second spacerconfigured to fit within the second cage and move in the second lateraldirection, the second spacer and the second cage configured such thatone or more second branches will move from an unextended position to afully extended position when the second spacer is urged in the secondlateral direction; wherein the second internal volume between the secondproximal end of the second seat and the second spacer is unoccupied byany link member when the one or more second branches are in the fullyextended position; wherein a first lateral-most edge portion of thefirst branches has a first unexpanded height when the one or more firstbranches are in the unextended position and a first expanded height whenthe one or more first branches are in the fully extended position;wherein a second lateral-most edge portion of the second branches has asecond unexpanded height when the one or more second branches are in theunextended position and a second expanded height when the one or moresecond branches are in the fully extended position; wherein the firstseat has a first seat height; wherein the first seat height is (a)greater than the first and second unexpanded heights, and (b) less thanthe first and second expanded heights.
 16. The intervertebral spacingimplant system of claim 15, wherein the spacer-advancing instrument isconfigured to simultaneously advance the first and second spacers in thefirst and second lateral directions in response to rotating a portion ofthe spacer-advancing instrument.
 17. The intervertebral spacing implantsystem of claim 16, wherein the spacer-advancing instrument isconfigured to asynchronously and simultaneously laterally advance thefirst and second spacers in response to rotating a portion of thespacer-advancing instrument.
 18. The intervertebral spacing implantsystem of claim 15, wherein an additional one of the first branches islocated between the one of the first branches and the another of thefirst branches.
 19. The intervertebral spacing implant system of claim15 comprising: a first orifice extending from the first internal volumeof the first cage and through the first seat to the second seat, theorifice configured to allow the spacer-advancing instrument to passthrough; a second orifice extending from the second internal volume ofthe second cage and through the second seat to the first seat, thesecond orifice configured to allow the spacer-advancing instrument topass through; wherein the first and second seats are non-resilient.